DE1937619B2 - ARRANGEMENT FOR DAMPING VIBRATIONS ARISING FROM A BUILDING - Google Patents

Description

The invention relates to an arrangement for damping vibrations occurring on a building and lying below the sound range, e.g. B. as a result of wind load, unte ^r use of damping units with at least two rigid members that are connected to one another by at least one elastic layer.

Large structures become vibrations that are below the sound range due to the action of the wind offset. It is desirable to keep these vibrations as small as possible so that such vibrations are not noticed and that the facilities in the structures are not damaged.

In French patent specification 13 83 463 an arrangement is provided which provides a viscoelastic layer between two essentially rigid elements in order, with the aid of the viscoelastic layer, to absorb vibrations which occur between the rigid 619

Elements occur. The purpose of the arrangement according to said French patent specification is in preventing sound vibrations from spreading. Similarly, the magazine reveals "Building Materials" from August 1964 on p. 16 to 18 a rubber mounting that has a high compression resistance and takes up heavy loads acting in a vertical direction. In the magazine "Floor, Wall and Ceiling" from July 1966 on p. 608 also shows a rubber bearing with which sound vibrations should be prevented from moving from one part of a structure to another reach.

However, the above prior art cannot contribute to solving the problem, as in FIG high structures, for example, vibrations generated by wind below the sound range are dampened could. The use of rubber bearings of the known type would be quite contrary to the The desired effect is a tall structure with regard to the vibrations mentioned in the subsonic range make it much more vulnerable.

So far, attempts have essentially been made to control such vibrations in that high Structures were made more rigid, d. H. by making stronger Supports or braces were used between the supports. Wear such stiffeners however, it helps to drive up the cost of a structure, both because of the additional Cost of the added bracing as well as the fact that the structure is thereby becomes heavier overall.

The present invention is based on the object of vibrations lying in the subsonic range on high structures without having to make the building itself more massive.

According to the invention, this object is achieved in that the elastic layer is made of viscoelastic material consists and that the rigid members of the damping units with two points of the structure, which as a result of the vibrations to be damped are subjected to a relative movement, are connected in such a way that between a shear movement occurs to them, which the elastic layer resists, this being essentially is free from static loads.

The rigid links are provided with fastening means with which a connection between two Points of the structure can be produced in which as a result of the vibrations mentioned a relative movement occurs. At one of the points on the building there is a rigid link of the damping unit attached, while the adjacent rigid member is attached to the other point, so that the vibrations are dampened by shear forces within the viscoelastic layer.

The damping unit according to the invention connects the girders or cross members of a building with the Pillars essentially in the plane of the ceiling or the floor above. With such a Installation are the vibrations below the sound range, which are a relative movement in buildings cause between pillars and girders in the plane of the slabs, from those in the viscoelastic Layers occurring shear forces are significantly dampened. With an arrangement of the damping units They are also in the space between the ceiling and the floor of the floor above easily accessible so that it is periodically monitored and

if necessary, can graze replaced.

An advantageous embodiment of the arrangement according to the invention is characterized in that the Damping unit consists of three rigid members that are connected to each other by two viscoelastic layers are connected, the two outer links that accommodate the third link between them, with the same Point of the structure are connected and the third link with an opposite point of the Structure is connected

According to a further embodiment of the invention, the viscoelastic layer should have a loss factor of have at least 0.5.

Preferably, the glass transition temperature of the viscoelastic layer between +5 and -50 ⁰ C should be located. Furthermore, the viscoelastic layer should have a shear strength of at least 14 kg / cm ² and an elongation at break of at least 100%.

The viscoelastic material and the adhesive should remain stable and stable for a long time in normal use, primarily at normal room temperatures, since the locations in which the damping units are to be installed are generally air-conditioned. The above-mentioned requirements for the viscoelastic layer can be met if it consists of a copolymer of acrylic monomers, such as acrylic acid, methacrylic acid, alkyl acrylate. Acrylonitrile, methacrylonitrile, acrylamide and methacrylamide. The alkyl acrylate can consist of a single monomer having about 6 to 10 carbon atoms in the alkyl group that is not highly branched, that is, more than half of the alkyl carbon atoms are in a straight chain that terminates in an oxygen bridge. If the alkyl acrylate consists of a mixture of monomers, their alkyl groups should have an average of about 6 to 10 carbon atoms, and less than half of the alkyl groups should be highly branched. Within the range of about 60 to 85 parts alkyl acrylate and correspondingly from 15 to 40 parts of one or ^ ₀ more of said copolymerizable akrylischen monomers using compatible copolymers are obtained which also prolonged exposure of Umgebung.iluft and at normal room temperatures no disintegration phenomena or changes to show.

The invention will now be described in detail. In the drawing shows

Fig. 1 is a schematically illustrated side view of a damping unit according to the invention,

2 shows an enlarged section through part of the FIG. 1 after line 2-2,

F i g. 3 shows a schematically drawn side view of a detail of the damping unit according to FIG. 1,

4 shows a schematic representation of a in a Structure built-in damping unit according to the invention,

5 shows a schematic representation of a damping unit which forms part of a load-bearing device forms,

F i g. 6 shows a schematic representation of another embodiment of the damping unit installed in a building according to the invention,

7 shows a cross section along line 8-8 in FIG. 6,

8 shows a representation of a third embodiment of a damping unit built into a structure according to the invention.

The damping unit shown in Fig. 1 is composed of three rigid members. Two of these Links 11, 11 'have the flanges 12, 12' and the plates 13, 13 '. The third link consists of one flat rail 14, the wide sides of which between the flanges 12,12 'with substantially the same small Distances from these are located in the spaces between the surfaces of the rail 14 and the Flanges 12, 12 'are the viscoelastic layers 15, 15' each with adhesive coatings 16, 16 '; as in FIG. 2 shown.

The damping unit 10 is suitably assembled using preformed ones Layers of the viscoelastic material, starting with a sub-arrangement according to FIG. At each end of the viscoelastic layer 15 are two self-adhesive by means of their own adhesive coverings Strips 21 attached, which extend over the entire width of the viscoelastic layer and a spacer 18 a short distance from the end of the viscoelastic layer take up between them. An adhesive coating 16 is placed on one side of the viscoelastic layer 15 applied and applied to the flange 12. The other side of the viscoelastic layer is then covered with a second adhesive coating 16 is provided, to which the rail 14 is applied. After that, a second viscoelastic Layer 15 'provided with an adhesive coating 16' and to which a second adhesive coating 16 ' provided exposed side of the rail 14, while the other flange 12 'on the open Adhesive attachment 16 'is applied. Four screw nuts

17 are then firmly tightened against the screw bolts 18 via spring washers 23, the diameter of which is dimensioned so that the adhesive of the adhesive coatings 16, 16 'on the entire circumference of each viscoelastic Layer is pressed out. The nuts 17 are kept tensioned until the adhesive coverings 16, 16 'are completely cured with certainty, and until the damping unit 10 at the point of use has been attached, for which purpose the fastening means in the form of the holes 19 ', 19' to the Plates 13 ', 13' and the holes 20 on an extension 22 of the rail 14 can be used.

After the glue seeps out, the excess glue and the excess become viscoelastic Material cut off at the sides. The self-adhesive strips 21 prevent mutual Touching the adjacent viscoelastic layers at the ends.

According to FIG. 4, the damping unit 10 can be positioned between a supporting pillar 40 and a carrier 41 are arranged approximately at the level of the ceiling of the room below the beam. With With the aid of the screw bolts 20a passed through the holes 20 on the rail, the damping unit becomes 10 attached to the support 41, while the screw bolts passed through the holes 19, 19 ' 19a hold the plates 13, 13 'on the pillar 40. To After attaching the damping unit 10, the screw bolts 18 can be removed. The bolts

18 are preferably only loosened to the extent that a free relative longitudinal movement is possible with certainty is, however, without completely relaxing the spring washers 23, whereby a separation as a result of a not force acting in the longitudinal direction is prevented. For this purpose, the holes on the rail 14 a little wider than necessary so that

there is enough play for the screw bolts to allow the relative longitudinal movement between the rail 14 and not to obstruct the flanges 12, 12 '.

The carrier 41 is attached to the pillar 40 approximately at the level of the floor above, so that at Vibrations of the structure, the flanges 12, 12 'and the rail 14 to and fro relative to one another move forward and thereby exert horizontal shear forces on the viscoelastic layers 15, 15 '. To this The viscoelastic layers 15, 15 'absorb the kinetic energy of the vibrations. in the In the present case, the damping units 10 do not act as bearing means.

The damping unit 10 according to the invention can be installed in a load-bearing device 50, as shown in Fig. 5, the load being borne by a spring 51, while the damping unit 10 dampens load oscillations. Fastening means are provided at the ends of the spring 51 and the damping unit 10 52 and 53 are provided with which the load-bearing device 50 is held in place can be. Instead of a single spring, the damping unit 10 can be in the middle between two or more springs arranged or used in conjunction with other types of load bearing members, which are elastically or resiliently mounted and a relative movement in the direction along the line between the Allow fasteners 52 and 53.

6 to 8 show various other embodiments and possible uses of the damping unit according to the invention. The in the F i g. 6 and 7 shown damping unit 70 consists made of two rigid links 71, 72, in the form of rails, which are separated from one another by a viscoelastic layer 73. With the bolt 74 this is relatively wide member 71 attached to the underside of a carrier 75, which is at the top of a Pillar 76 is attached. The link 72 is attached to the pillar 76 by means of screw bolts 77. if if desired, the rigid member 71 can be omitted, the carrier 75 having a planar Underside is provided, to which the viscoelastic layer is glued directly. In this case it will Member 72 is screwed to the support 75 until between the viscoelastic layer 73 and the surface of the Support 75 is made a solid connection. The bolts used can then be loosened, however, be left in a loosened state in order to prevent the cushioning unit 70 from falling off the wearer 75 is separated, assuming that the holes for the bolts are slightly wider than required to be dimensioned.

According to FIG. 8, a beam 80 with a pillar 81 can be used can be connected by two damping units 82, 83, each unit of which is equal to the damping unit 70 and attached to carrier 80 except that means are provided that a compression of the viscoelastic layer 85 by the weight of the carrier 80 prevent, the means 84 z. B. can consist of roller bearings that allow a longitudinal movement of the carrier 80 enable. The bracket 80 can be fixedly attached at the other end to another pillar or in the in the Fi g. 6 are attached in the manner shown. If desired, both ends of the bracket 80 can do so be connected, as shown in Figure 8, without that there is a rigid connection with the pillars. Such a free-floating arrangement causes a high degree of damping of vibrations lying below the sound range in the carrier 80 and in the overlying floor. Such vibrations were previously found in floors that were over extended pillar-free districts were a nuisance.

The in the F i g. The arrangement shown in FIG. 8 can be modified in such a way that the carrier 80 is in the The middle of the carrier 86 is additionally rigidly attached to the pillar 81. The damping units 82, 83 act a damping of the bending forces in the pillar, while the arrangement according to FIG. 8 also a damping dei Reciprocating motion of the carrier 80 with respect to FIG

Pillar 81 would effect.

For this purpose 3 sheets of drawings

Claims (6)

Claims: 1937 3 1. Arrangement for attenuating those occurring on a building, below the sound range lying vibrations, e.g. B. as a result of wind loads, using damping units with at least two rigid members that are connected to each other by at least one elastic layer are connected, characterized in that the elastic layer (15, 15 '; 73) from viscoelastic material and that the rigid members (11, 11 '; 14; 71, 72) of the damping units (10; 70) with two points of the structure, which are subjected to a relative movement as a result of the vibrations to be damped, connected in this way are that between them a shear movement occurs, which the elastic layer (15, 15 '; 73) Resistance, which is essentially free of static stress. 2. Arrangement according to claim 1, characterized in that that the damping unit (10) consists of three rigid members (11, 11 'and 14) through two viscoelastic layers (15 and 15 ') are joined together, the two outer members (11 and 11 ') that have the third link (14) between them record, are connected to the same point of the structure and the third link (14) with a opposite point of the structure is connected. 3. Arrangement according to one of claims 1 to 2, characterized in that the viscoelastic layer (15, 15 '; 73) has a shear strength of at least 14 kg / cm ² and an elongation at break of at least 100% 4. Arrangement according to one of claims 1 to 3, characterized in that the viscoelastic Layer (15, 15 '; 73) has a loss factor of at least 0.5. 5. Arrangement according to one of claims 1 to 4, characterized in that the glass transition temperature of the viscoelastic layer (15, 15 '; 73) is 5 to -50 "C. 6. Arrangement according to one of claims 1 to 5, characterized in that the viscoelastic Layer (15, 15 '; 73) consists of a copolymer of acrylic monomers.